DE20301317U1 - Circuit arrangement for measuring and limiting currents - Google Patents

Abstract

A current measurement and limiting unit has conductor (20) input and surface mount device thick film (19) measurement resistances attached to a direct current interface circuit (13) capacitor between an inverter (15) and mains (11) bridge rectifier (12) with computed value controlling an output current limiting circuit (9).

Description

AP 174 DEGM
Fg/ma

Diehl AKO Foundation & Co. KG, 88227 Wangen Circuit arrangement for measuring and limiting currents

The invention relates to a circuit arrangement according to the preamble of claim 1.

Such a circuit arrangement is known from DE 198 34 315, Figure 6. It essentially consists of a rectifier bridge connected to the mains, a DC intermediate circuit and a six-pulse converter fed from it, which feeds a three-phase motor. A measuring resistor is arranged between the rectifier bridge and the DC intermediate circuit and between this and the converter. The latter, rear measuring resistor measures the converter current from the DC intermediate circuit, the front measuring resistor measures the input current drawn from the mains. This can be used as a control variable for actively controlling the current consumption from the mains by means of a current limiter circuit. This makes it possible to reduce the effective current, improve the power factor (so-called power factor control, PFC) or limit the power consumption from the mains to the maximum value that does not trigger the mains fuse despite the momentary higher power demand. Since this front measuring resistor must be designed in such a way that it can withstand high current peaks without damage, especially when charging a discharged intermediate circuit capacitor, a pulse-resistant resistor must be used here, which has a very high unit price and, due to its dimensions, is generally not suitable for automatic assembly of the circuit arrangement.

In recognition of these circumstances, the present invention is based on the technical problem of providing a circuit arrangement for measuring a

Converters are designed to provide mains current via a DC intermediate circuit, which is designed in such a way that a special pulse-proof resistor is not required.

This object is achieved according to the invention by the essential features specified in the main claims. According to this, a conductor track of the circuit arrangement itself is used as the input current measuring resistor before the DC voltage intermediate circuit. A conventional resistor, such as an SMD thick-film resistor, is used as the output current measuring resistor, after the DC voltage intermediate circuit.

The inventive determination of the mains current drawn via a DC intermediate circuit is therefore based on a voltage measurement at measuring resistors before and after the DC intermediate circuit. Since the intermediate circuit capacitor on average delivers as much charge to the converter as it previously took in from the mains, the input current before and the output current after the DC intermediate circuit are on average the same. They can be described by voltage and resistance according to Ohm's law. The initially undetermined size of the input current measuring resistor is thus obtained from the known size of the output current measuring resistor multiplied by the quotient of the measured voltages at the input current measuring resistor and the output current measuring resistor. If the voltage is measured at the two measuring resistors continuously or quasi-continuously, a current period average can be determined from this.

The determined input current is a measure of the power consumption from the mains. It can be influenced by a current limiter and can therefore influence the power factor without requiring an expensive pulse-proof special resistor for measuring the mains current.

Additional developments and further features and advantages of the invention emerge from the further claims and from the following description of a block diagram of the inventive solution sketched in the drawing with restriction to the essentials.

The only figure in the drawing schematically shows the simplified topology of a circuit arrangement 10 according to the invention for active power factor correction by controlling the current consumption from a network 11. An intermediate circuit capacitor 14 located in a DC voltage intermediate circuit 13 is charged via a rectifier bridge 12, which is connected to the network 11. From this, the rotating field motor 18 connected downstream is fed in accordance with the control of switching means 16 and 17 in the half branches of a converter 15, and the intermediate circuit capacitor 14 is discharged accordingly. The intermediate circuit capacitor 14 is recharged from the network 11 via the rectifier bridge 12.

The current from the DC intermediate circuit 13 flows to the converter via a measuring resistor 19. The current is determined at this output current measuring resistor 19 with a known value Ru by measuring a voltage drop URu. A front measuring resistor 20 is connected between the DC intermediate circuit 13 and the rectifier bridge 12 to measure an input current Ie. This input current Ie determined here can be used to control the mains current consumption for recharging the intermediate circuit capacitor 14 via a current limiter circuit 9.

The input current measuring resistor 20 in front of the DC voltage intermediate circuit 13 is a conductor track of the circuit 10 itself, on which a voltage drop URe is measured. The quotient of this voltage drop URe and the size Re of the input current measuring resistor 20 provides the input current Ie.

The small voltage drops URu and URe tapped at the measuring resistors 19 and 20 are amplified by an amplifier 21 and 22 to a processing level for an analog-digital converter 23, which then feeds a control device 24 which controls the current limiter 9. The control device 24 is, for example, a micro-controller.

Depending on the measured voltage drop URe between the DC intermediate circuit 13 and the rectifier bridge 12, the current consumption from the network 11 is limited by means of a circuit 9, so that the

Power factor is improved due to harmonic damping by sinusoidal current consumption or, in the case of extreme mains impedance, the effective current consumption from the mains 11 is limited to a setpoint specified by an overcurrent protection device.

In order to determine the size Re of the input current measuring resistor 20, which is not clearly defined and cannot be reproduced due to the design as a conductor track, and thereby to compensate for errors which may arise, for example, due to layer thickness tolerances for the conductor track, non-uniform temperature coefficients, oxidation, etc.

, the measurement of the voltage drop URe is carried out at least quasi-continuously, as is the measurement of the voltage drop URu across the output current measuring resistor 19. From these measurements, the integral mean values of the voltage drop across the measuring resistors 19 and 20 are determined during a system period which is given by the reciprocal of the system frequency.

The method for measuring current makes use of the fact that a charge flowing through the input current measuring resistor 20 to charge the intermediate circuit capacitor 14 flows back out with an identical amount through the output current measuring resistor 19 during its subsequent discharge to supply the converter 15. As a result, the average value of the current flow Ie through the input current measuring resistor 20 during a network period is equal to the average value of the current flow Iu through the output current measuring resistor 19 during a network period.

According to Ohm's law, the period mean value of the current flow Ie or Iu across one of the measuring resistors 20 or 19 is described by the quotient of the mean value of the input voltage drop URe or the output voltage drop URu across the measuring resistor 20 or 19 during a network period and the size Re or Ru of the measuring resistor 20 or 19.

As stated above, the voltage drop URe and URu is measured at the measuring resistors 20 and 19. The size Ru of the output current measuring resistor 19 is also known. However, to measure the current flow Ie, it is necessary to determine the indeterminate value Re of the input current measuring resistor 20. This is done by an evaluation (weighting, i.e. multiplication).

on) of the value Ru of the output current measuring resistor 19 with the quotient of the currently measured period mean values of the input voltage drop URe at the measuring resistor 20 and the output voltage drop URu at the measuring resistor 19.

Preferably, the voltage drop across the two measuring resistors 19 and 20 is measured continuously. Depending on the measured input voltage drop URe between the DC voltage intermediate circuit 13 and the rectifier bridge 12, the current consumption from the network 11 can be regulated, i.e. limited, via a current limiter 9 or by limiting the motor power via the converter 15.

An easily mounted SMD thick-film resistor can be used as the output current measuring resistor 19 for measuring the output voltage drop URu behind the DC voltage intermediate circuit 13.

According to the invention, a circuit arrangement 10 for determining the current Ie drawn from the network 11 by a converter 15 via a DC voltage intermediate circuit 13 replaces the pulse-resistant input current measuring resistor 20 required per se by a conductor track of the circuit arrangement itself.

Since the input current Ie taken from the network 11 by the DC intermediate circuit 13 is on average equal to the output current Iu delivered to the converter 15, the current resistance value Re of the conductor track is given by the resistance value Ru of the measuring resistor 19 behind the DC intermediate circuit 13, weighted with the quotient URe/URu from the input and output voltage drop. In this way, the network current and thus the power factor can be influenced via a current limiter 9 without requiring an expensive pulse-proof special resistor for the network current measurement.

Claims (8)

1. Circuit arrangement ( 10 ) for determining the current drawn by a converter ( 15 ) via a DC voltage intermediate circuit ( 13 ) with measuring resistors ( 20 , 19 ) before and after the DC voltage intermediate circuit ( 13 ), characterized in that the input current measuring resistor ( 20 ) is a conductor track before the DC voltage intermediate circuit ( 13 ) of the circuit arrangement ( 10 ) itself. 2. Circuit arrangement according to claim 1, characterized in that the output current measuring resistor ( 19 ) behind the DC voltage intermediate circuit ( 13 ) is a conventional resistor. 3. Circuit arrangement according to claim 2, characterized in that the output current measuring resistor ( 19 ) is an SMD thick-film resistor. 4. Circuit arrangement according to one of the preceding claims, for determining the input current (Ie) drawn from a converter ( 15 ) via a DC voltage intermediate circuit ( 13 ) by means of voltage measurement at measuring resistors ( 20 , 19 ) before and after the DC voltage intermediate circuit ( 13 ), wherein the input current (Ie) before the DC voltage intermediate circuit ( 13 ) is determined as the quotient of voltage drop (URe) and size (Re) of the input current measuring resistor ( 20 ), characterized in that the known output current measuring resistor (Ru, 19) behind the DC voltage intermediate circuit ( 13 ) is evaluated as the size of the input current measuring resistor (Re, 20) with the quotient (URe/URu) of the currently measured period mean value of the input and output voltage drops. 5. Circuit arrangement according to claim 4, characterized in that the measurement of the voltage drop across both current measuring resistors ( 19 , 20 ) is carried out at least quasi-continuously. 6. Circuit arrangement according to claim 5, characterized in that depending on the measured voltage drop (URe) between the DC voltage intermediate circuit ( 13 ) and the rectifier bridge ( 12 ), the current consumption from the network ( 11 ) is limited by means of a circuit ( 9 ), so that the power factor is improved as a result of damping of harmonics by sinusoidal current consumption or, even in the case of extreme network impedance, the effective current consumption from the network ( 11 ) is limited to a target value dependent on the given fuse. 7. Circuit arrangement according to claim 6, characterized in that the voltage drop (URu) is determined by means of the current (Iu) flowing from the DC voltage intermediate circuit ( 13 ) to the converter ( 15 ) via an SMD thick-film resistor. 8. Circuit arrangement according to one of claims 1 to 5, characterized in that the current consumption from the mains is limited by limiting the motor power when the effective current drawn from the mains threatens to exceed a limit value dependent on the response of a fuse.